Interference avoidance for beamforming transmissions in wireless communication devices and systems

ABSTRACT

Systems, apparatuses, and techniques for interference avoidance beamforming transmissions are described. A described apparatus can be configured to control a first channel sounding process with the first device to obtain first channel feedback regarding a wireless channel between the apparatus and the first device, determine, responsive to the first channel feedback, a first matrix to improve a performance of the beamforming transmission with respect to the first device, control a second channel sounding process with a second device to obtain second channel feedback regarding a wireless channel between the apparatus and the second device, determine, responsive to the second channel feedback, a second matrix to reduce interference leakage received by the second device during the beamforming transmission, and control the beamforming transmission to the first device based on the data and a steering matrix, the steering matrix being based on the first matrix and the second matrix.

CROSS REFERENCE TO RELATED APPLICATIONS

This disclosure is a continuation application of and claims the benefitof priority under 35 USC 120 of U.S. application Ser. No. 14/340,492,filed Jul. 24, 2014, which claims the benefit of the priority of U.S.provisional Application Ser. No. 61/859,065, filed Jul. 26, 2013, theabove-identified applications are incorporated herein by reference intheir entirety.

BACKGROUND

Wireless Local Area Networks (WLANs) include multiple wirelesscommunication devices that communicate over one or more wirelesschannels. When operating in an infrastructure mode, a wirelesscommunication device called an access point (AP) provides connectivitywith a network such as the Internet to other wireless communicationdevices, e.g., client stations or access terminals (AT). Variousexamples of wireless communication devices include mobile phones, smartphones, wireless routers, wireless hubs. In some cases, wirelesscommunication electronics are integrated with data processing equipmentsuch as laptops, personal digital assistants, and computers.

Wireless networks such as WLANs can use one or more wirelesscommunication technologies such as orthogonal frequency divisionmultiplexing (OFDM). In an OFDM based wireless communication system, adata stream is split into multiple data substreams. Such data substreamsare sent over different OFDM subcarriers, which can be referred to astones or frequency tones. Some wireless networks use asingle-in-single-out (SISO) communication approach, where each wirelesscommunication device uses a single antenna. Other wireless networks usea multiple-in-multiple-out (MIMO) communication approach, where awireless communication device uses multiple transmit antennas andmultiple receive antennas. WLANs such as those defined in the Instituteof Electrical and Electronics Engineers (IEEE) wireless communicationsstandards, e.g., IEEE 802.11a, IEEE 802.11n, IEEE 802.11ac, can use OFDMto transmit and receive signals. Moreover, WLANs, such as ones based onthe IEEE 802.11n or IEEE 802.11ac standards, can use OFDM and MIMO.

SUMMARY

The present disclosure includes systems and techniques for interferenceavoidance beamforming transmissions. According to an aspect of thedescribed systems and techniques, a method for interference avoidancebeamforming transmissions includes accessing, at a first device, datafor transmission to a second device; performing, at the first device, achannel sounding process with a third device to obtain channel feedbackregarding a wireless channel between the first device and the thirddevice; determining a steering matrix based on the channel feedback toreduce interference leakage received by the third device during abeamforming transmission from the first device to the second device; andperforming, at the first device, the beamforming transmission to thesecond device based on the data and the steeling matrix.

The described systems and techniques can be implemented in electroniccircuitry, computer hardware, firmware, software, or in combinations ofthem, such as the structural means disclosed in this specification andstructural equivalents thereof. This can include at least onecomputer-readable medium embodying a program operable to cause one ormore data processing apparatus a signal processing device including aprogrammable processor) to perform operations described. Thus, programimplementations can be realized from a disclosed method, system, orapparatus, and apparatus implementations can be realized from adisclosed system, computer-readable medium, or method. Similarly, methodimplementations can be realized from a disclosed system,computer-readable medium, or apparatus, and system implementations canbe realized from a disclosed method, computer-readable medium, orapparatus.

For example, one or more disclosed embodiments can be implemented invarious systems and apparatus, including, but not limited to, a specialpurpose data processing apparatus (e.g., a wireless communication devicesuch as a wireless access point, a remote environment monitor, a router,a switch, a computer system component, a medium access unit), a mobiledata processing apparatus a wireless client, a cellular telephone, asmart phone, a personal digital assistant (PDA), a mobile computer, adigital camera), a general purpose data processing apparatus such as acomputer, or combinations of these.

Particular configurations of the technology described in this disclosurecan be implemented so as to realize one or more of the followingpotential advantages. During a beamforming transmission to an intendeddevice, a described technique can reduce an interference signalassociated with the beamforming transmission that is experienced by animpacted device. A described technique can minimize interference betweenoverlapping basic service sets by allowing a sounding process betweentwo or more basic service sets to take place. A described technique canincrease spectrum efficiency, wireless network density, or both.

Details of one or more implementations are set forth in the accompanyingdrawings and the description below. Other features and advantages may beapparent from the description and drawings, and from the claims.

DRAWING DESCRIPTIONS

FIG. 1 shows an example of interference between different wireless localarea networks during a nominal beamforming transmission.

FIG. 2 shows a simplified block diagram of a wireless communicationdevice 205.

FIG. 3 shows an example of an interference avoidance beamformingtransmission process.

FIG. 4 shows an example of an interference avoidance beamformingtransmission process that uses explicit sounding.

FIG. 5 shows an example of an interference avoidance beamformingtransmission process that uses explicit sounding for intended andimpacted devices.

FIG. 6 shows an example of sounding processes associated with aninterference avoidance beamforming transmission.

FIG. 7 shows an example of a wireless communication sequence thatincludes an explicit sounding sequence for an interference avoidancebeamforming transmission.

FIG. 8 shows an example of a wireless communication sequence thatincludes an explicit sounding sequence with multiple impacted devicesfor an interference avoidance beamforming transmission.

FIG. 9 shows an example of a wireless communication sequence thatincludes an implicit sounding sequence for an interference avoidancebeamforming transmission.

Like reference symbols in the various drawings indicate like elements.

DETAILED DESCRIPTION

A wireless network such as a WLAN can select from two or morepredetermined frequency bands an operational frequency band for use inits Basic Service Set (BSS). Different networks can use differentfrequency bands to minimize interference. However, densely deployedwireless networks may experience Co-Channel Interference (CCI) fromOverlapping Basic Service Sets (OBSS). For example, in the 2.4 GHz bandfor IEEE 802.11, there are only three 20 MHz channels, so frequencyreuse may be very low which can result in OBSS collisions, e.g., wheretwo basic service sets have to share the same frequency band.

When an OBSS collision happens, interference and performance degradationmay occur and can have an impact on unicast packets (e.g., data frames)and broadcast packets (e.g. management frames, control frames). For aunicast packet, an OBSS collision can trigger a Clear Channel Assessment(CCA) and possible physical (PHY) layer decoding. Here, packetprocessing may cease at the medium access control (MAC) layer when a MACaddress mismatch happens, however, CCA can continue to the end of thepacket, hence packet transmission is blocked. For a broadcast packet,such as a management frame, an OBSS collision can result in the MAClayer to continue processing the management frame till the end of thepacket, setting a long network allocation vector (NAV) that blocks itsown transmissions.

While a wireless network may use transmission beamforming (TxBF) tosteer signals within a BSS, interference may result with another BSS orthe same BSS. This disclosure proposes interference avoidancetransmission beamforming (IA-TxBF) inch transmission beamforming isperformed with an intended device while avoiding interference leakage toother devices, which could be in the same BSS or a different,overlapping BSS.

FIG. 1 shows an example of interference between different wireless localarea networks during a nominal beamforming transmission. Devices 110 a-ccan communicate via a wireless channel within an operating environment101. The operating environment 101 can include devices 110 a-bassociated with BSS-A 105 a and one or more devices 110 c associatedwith a BSS-B 105 b. In this example, BSS-A 105 a and BSS-B 105 b areforced to operate in the same frequency band. The “interfering” device110 a performs a nominal beamforming transmission 120 to an “intended”device 110 b using two or more antennas. Unfortunately, the nominalbeamforming transmission 120 can cause interference to other devicessuch as an “impacted” device 110 c, which degrades the performance ofthe impacted device 110 c. However, by using an interference avoidanceprocedure described herein, the nominal beamforming transmission 120 isreplaced by an interference avoidance (IA) beamforming transmission thatis steered to reduce interference to the impacted device 110 c bydirecting most of its energy towards the intended device 110 b and awayfrom the impacted device 110 c.

FIG. 2 shows a simplified block diagram of a wireless communicationdevice 205. The device 205 can include processor electronics 210 such asone or more processors that implement methods effecting the techniquespresented in this disclosure. Various examples of device 205 includeaccess point (AP), base station (BS), access terminal (AT), clientstation, or mobile station (MS). The device 205 can include transceiverelectronics 215 to send and/or receive wireless signals over one or moreantennas 220 a-b. In some implementations, transceiver electronics 215can include multiple radio units. In some implementations, a radio unitincludes a baseband unit (BBU) and a radio frequency unit (RFU) totransmit and receive signals. The device 205 can include one or morememories 225 configured to store information such as data and/orinstructions. In some implementations, the device 205 includes dedicatedcircuitry for transmitting and dedicated circuitry for receiving. Thedevice 205 can be configured to transmit a beamforming signal, receive abeamforming signal, or both.

FIG. 3 shows an example of an interference avoidance beamformingtransmission process. This process can be implemented by a wirelesscommunication device such as the device 205 depicted by FIG. 2. At 305,the process accesses data for a beamforming transmission to an intendeddevice. Accessing data can including receive a data unit from a higherlayer at a MAC layer.

At 310, the process performs a channel sounding process with an impacteddevice to obtain channel feedback regarding a wireless channel that isformed with the impacted device. Various examples of a channel soundingprocess include an explicit channel sounding process or implicitsounding process. Performing an explicit channel sounding process caninclude transmitting a sounding announcement packet to the impacteddevice, transmitting a sounding packet, and receiving channel feedbackfrom the second device. In some implementations, the soundingannouncement packet can include an interference avoidance indicator toinform the recipient that the sounding packet is for an interferenceavoidance determination. Performing an implicit channel sounding processcan include receiving a sounding announcement packet from the impacteddevice, receiving a sounding packet, and determining the channelfeedback based on the sounding packet.

At 315, the process determines a steering matrix based on the channelfeedback to reduce interference leakage received by the impacted deviceduring the beamforming transmission to the intended device. In someimplementations, determining the steering matrix can include determininga null space of a wireless channel matrix that represents a wirelesschannel formed with the impacted device.

At 320, the process performs the beamforming transmission to theintended device based on the data and the steering matrix. Performingthe beamforming transmission can include applying the steering matrix toan information vector that represents at least a portion of the data. Insome implementations, the beamforming transmission can include data formultiple intended devices using multi-user beamforming transmission(MU-TxBF).

A sounding process can be used to determine one or more parameters suchas a steering matrix for a beamforming transmission. Responsive to asounding process, a device can obtain or perform channel estimation of awireless channel formed between pairs of antennas on different devicesto assist in transmitting data, decoding of a received signal, or both.The channel can be represented by the channel matrix H. Performingchannel estimation can including computing a full-dimensional MIMOchannel matrix H in each sampled subcarrier of a MIMO-OFDM system. Insome implementations, a device uses channel estimation data to shapemulti-antenna communications such as spatial multiplexing orbeamforming. In some implementations, a device can determine one or morewireless channel matrices H_(i) ^(k) for respective subcarriers, e.g.,OFDM tones, based on one or more received signals, where H_(i) ^(k)represents the channel conditions for the k-th tone associated with thei-th receiver. Note that the k-th superscript in H_(i) ^(k) can bedropped for clarity. Further, it can be assumed that an operationinvolving H_(i) can apply to one or more channel matrices for one ormore subcarriers.

A transmitter device can perform a single user beamforming transmission(SU-TxBF) to a single receiver device using a steering matrix Q thatdirects the signal output of two or more antennas towards the singlereceiver. The steering matrix Q can be a function of a channel matrix Hcorresponding to a channel between the transmitter and the receiver. Insome implementations, a transmitter can perform a MU-TxBF to two or morereceivers using steering matrices Q_(i) that directs the signal outputof multiple antennas towards the receivers, the signal output forms twoor more dominant radiation lobes that coincide with the locations of thetwo or more receivers. Thus, a MU-TxBF can concurrently provide data tothe two or more receivers via different spatial wireless channels withinthe same transmission frame. The transmitter can use a MU-TxBF OFDMtransmission signal model based on

$s = {\sum\limits_{i = 1}^{N}{Q_{i}x_{i}}}$where s is a transmitted signal vector for an OFDM tone, N is a numberof simultaneously serviced receivers, x_(i) is an information vectorintended for the i-th receiver, and Q_(i) is a steering matrix for thei-th receiver.

In a MU-TxBF model where data for multiple users are transmitted in thesame packet, a received signal can include a signal component intendedfor the i-th receiver and one or more co-channel interference componentsfrom one or more signals intended for one or more other receivers. Forexample, a received signal at the i-th receiver can be expressed by:

$y_{i} = {{H_{i}Q_{i}x_{i}} + {H_{i}{\sum\limits_{k \neq i}{Q_{k}x_{k}}}} + n_{i}}$where H_(i) represents a wireless channel matrix associated with awireless channel between a transmitter and the i-th receiver, Q_(i) is asteering matrix for the i-th receiver, and n_(i) represents noise at thei-th receiver. The summation term represents the co-channel interferencecomponents and the summation is performed over values of j correspondingto receivers other than the i-th receiver.

In IA-TxBF, each packet can provide data for a receiver device, which issimilar to SU-TxBF. However, a goal of IA-TxBF is to cancel or minimizeinterference leakage to other receivers such as a receiver in adifferent BSS. In a IA-TxBF model, a received signal at an intendedreceiver in one subcarrier is represented by y_(i)=H_(i)Q_(i)x_(i)+n_(i)whereas the leaked interference signal at an impacted receiver in onesubcarrier is represented by y_(L)=H_(L)Q_(i)x_(i)+n_(L), where channelmatrix H_(i) corresponds to a channel formed with the intended receiverand channel matrix H_(L) corresponds to a channel formed with theimpacted receiver.

For IA-TxBF to cancel interference leakage to an impacted receiver, asteering matrix Q_(i) can be designed with the following constraint:H_(L)Q_(i)=0 which can be realized by determining a Q_(i) such thatQ_(i)∈null(H_(L)), i.e., Q_(i) is in a null space of the leakage channelmatrix H_(L). Due to impairments and channel variations, absolute zero,i.e., absolute cancellation, may not be possible, however, the leakageat the impacted device can be minimized.

One example of the Q design for IA-TxBF can be expressed as follows:Q _(i) =V _(⊥H) _(L) ·V _(i)where V_(⊥H) _(L) is a null steering matrix which “steers” to the nullspace of H_(L); and V_(i) is the steering matrix that optimizes theperformance of the composite channel matrix H_(i).V_(⊥H) _(L) . Notethat V_(i) is computed and used only if H_(i) is also available,otherwise V_(i)=I where I is the identity matrix, or alternatively, theQ design becomes Q_(i)=V_(⊥H) _(L) .

In some implementations, a null steering matrix V_(⊥H) _(L) for achannel matrix H_(L) can be computed based on V_(⊥H) _(L) =I−V_(H) _(L)V*_(H) _(L) where V_(H) _(L) is the steering matrix for a channel matrixH_(L) and V*_(H) _(L) is the conjugate transpose of V_(H) _(L) . In someimplementations, V_(H) _(L) is determined by computing the singularvectors of H_(L). The singular vectors can be generated by using asingular value decomposition (SVD) technique. Note that the columns inV_(H) _(L) forms basis vectors of the null-space of the channel matrixH_(L). A sounding technique, such as explicit or implicit techniques asdescribed herein, can be used to determine associated channelinformation, e.g., the channel matrices, the V steering matrices, orboth, for IA-TxBF.

An interfering device can become aware of interference that it iscausing to an impacted device in the same BSS or another BSS. Based onover hearing a strong interfering signal from the interfering device,the impacted device can initiate an explicit sounding process by sendinga request such as a sounding request to the interfering device to causethe interfering device to send a sounding packet that is addressed tothe impacted device. In some implementations, the sounding packetincludes an null data packet (NDP) such as an NDP defined by IEEE 802.1In or 802.11ac. In some implementations, the interfering device sendsbefore the NDP, an NDP announcement frame that includes a MAC header.The MAC header can include a destination address of the impacted deviceand an indicator indicating that this is for an interference avoidancesounding process.

The impacted device receives the sounding packet, and uses it todetermine and send a feedback packet back to the interfering device. Insome implementations, the feedback packet includes CSI feedback such asquantized channel state information from the interfering device to theimpacted device, e.g., H_(L). In some implementations, the feedbackpacket includes compressed V matrix feedback. In some implementations,compressed V matrix feedback includes values for angles representing twoor more beamforming feedback matrices V that correspond to two or moreOFDM subcarriers. In some implementations, the feedback packet includesa compressed version of the null steering matrix V_(⊥H), which is basedon the CSI and is an orthogonal matrix so that it can be compressed fortransmission. In some implementations, V matrix feedback can be based onthe basis of CSI (e.g., singular vectors of an H matrix) as is the casefor SU-TxBF. In some implementations, the feedback packet includesnon-compressed V matrix feedback. For example, the feedback packetincludes non-compressed V matrix feedback such as a quantized steeringmatrix computed based on the CSI from the interfering device to theimpacted device; note that the V matrix is not required to be orthogonalfor the non-compressed case.

Based on the feedback, the interfering device computes IA-TxBF steeringmatrices. For CSI (e.g., H_(L)) feedback, the interfering device candetermine a Q_(i) for a beamforming transmission to the i-th device suchthat Q_(i)∈mull(H_(L)). For compressed or non-compressed V matrixfeedback in the case that feedback is null steering data, e.g., V_(⊥H)_(L) , then the interfering device can determine a Q_(i) directly fromthe feedback, e.g., Q_(i)=V_(⊥H) _(L) or Q_(i)=V_(⊥H) _(L) .V_(i) ifV_(i) has been determined via a sounding process with the i-th device.However, for compressed or non-compressed V matrix feedback in the casethat feedback is based on the basis of H_(L), e.g., V_(H) _(L) , theinterfering device can derive the null steering matrix V_(⊥H) _(L)=I−V_(H) _(L) V_(H) _(L) ^(H) before computing Q_(i) for a beamformingtransmission to the i-th device.

There can be multiple impacted devices. In such cases, the interferingdevice can perform explicit sounding by sending multiple soundingpackets to multiple impacted devices in the OBSS at the same time or atdifferent times. Alternatively, the interfering device can performimplicit sounding by receiving multiple sounding packets from multipleimpacted devices. The interfering device can jointly compute a steeringmatrix for IA-TxBF based on channel feedback from the multiple impacteddevices. For example, the interfering device can jointly compute anull-steering to the composite channel matrix to the impacted devices bydetermining Q_(i) for a beamforming transmission to the i-th device suchthat Q_(i)∈null(H_(L1), H_(L2), . . . ), where H_(L1), H_(L2), . . . arerespective channel matrices for channels between the interfering deviceand the impacted devices.

FIG. 4 shows an example of an interference avoidance beamformingtransmission process that uses explicit sounding. This process can beimplemented by a transmitter. At 405, the process performs a beamformingtransmission to an intended device. Performing the beamformingtransmission can include transmitting one or more steered frames to theintended device. At 410, the process determines whether a soundingrequest from an impacted device has been received. In someimplementations, an impacted device can send a sounding requestcontaining an interference avoidance indicator if the interference fromthe beam forming transmission exceeds a predetermined threshold. If asounding request has not been received, then the process continues toperform the beamforming transmission to the intended device at 405. If asounding request has been received, the process, at 415, transmits asounding packet having an interference avoidance indicator to theimpacted device. In some implementations, the sounding packet isannounced by a sounding announcement packet that has the interferenceavoidance indicator.

At 420, the process receives channel feedback from the impacted devicethat is based on the sounding packet. In some implementations, receivingchannel feedback can include receiving a packet containing a beamformingfeedback matrix, e.g., V_(H) _(L) . The beamforming feedback matrix canbe compressed. In some implementations, receiving channel feedback caninclude receiving a packet containing information that is indicative ofa channel. In some implementations, if the impacted device knows thatthis sounding is for interference avoidance, the impacted device cantransmit channel feedback containing a null space beamforming feedbackmatrix, e.g., V_(⊥H) _(L) .

At 425, the process determines a steering matrix based on the channelfeedback to reduce interference leakage received by the impacted deviceduring a next beamforming transmission into the intended device. In someimplementations, determining the steering matrix can include determininga null steering matrix responsive to the channel feedback. The nullsteering matrix can be based on a null space of a wireless channelmatrix associated with a wireless channel that is formed with theimpacted device. At 430, the process performs the next beamformingtransmission to the intended device based on data for the intended dataand the steering matrix.

FIG. 5 shows an example of an interference avoidance beamformingtransmission process that uses explicit sounding for intended andimpacted devices. At 505, the process transmits one or more soundingpackets to devices including an intended device of a beamformingtransmission and one or more impacted devices. A sounding packet caninclude signals based on pre-defined reference signals. A soundingpacket can include two or more segments for sounding two or moredifferent antennas.

At 510, the process receives feedback packets from the devices. Afeedback packet can include information that is derived from a wirelesschannel estimation that is based on a received sounding packet. In someimplementations, a feedback packet includes channel state information(CSI). In some implementations. CSI includes two or more signal-to-noiseratio values for two or more antennas being sounded by the soundingpacket. In some implementations, a feedback packet includes beamformingfeedback information such as a beamforming feedback matrix. In someimplementations, a feedback packet includes interference feedbackinformation such as an interference feedback matrix. Values thatconstitute matrix can be compressed for transmission.

At 515, the process determines an initial steering matrix based on thefeedback packet from the intended device that optimizes a performance ofthe beamforming transmission with respect to the intended device.Determining an initial steering matrix can include deriving a wirelesschannel matrix H based on CSI values in a feedback packet from theintended device. Determining an initial steering matrix can includeuncompressing a matrix V from compressed beamforming feedback matrixdata in a feedback packet from the intended device.

At 520, the process determines a null steering matrix based on the oneor more feedback packets from the one or more impacted devices. At 525,the process determines a revised steering matrix based on the initialsteering matrix and the null steering matrix. At 530, the processgenerates a steered data packet based on the steering matrix and datafor the intended device. At 535, the process transmits the steered datapacket to the intended device.

FIG. 6 shows an example of sounding processes associated with aninterference avoidance beamforming transmission. Devices 610 a-e cancommunicate via one or more wireless channels within an operatingenvironment 601. The interfering device 610 a can perform one or moresounding processes 615 a with one or more intended devices 610 b-c.Results of the one or more sounding processes 615 a can be used forSU-TxBF or MU-TxBF. Further, the interfering device 610 a can performone or more sounding processes 615 b with one or more one or moreimpacted devices 610 d-e. Results of the one or more sounding processes615 b can be used for interference avoidance versions of SU-TxBF orMU-TxBF. In some implementations, the interfering device 610 a canperform both of the sounding processes 615 a-b concurrently. In someimplementations, the interfering device 610 a only performs the one ormore sounding processes 615 b for interference avoidance if triggered byan interference avoidance request from an impacted device 610 d-e. Insome implementations, two or more types of soundings (e.g., explicit orimplicit) can be used for the sounding processes 615 a-b. For example,sounding process 615 a can be explicit, while sounding process 615 b canbe implicit.

FIG. 7 shows an example of a wireless communication sequence thatincludes an explicit sounding sequence for an interference avoidancebeamforming transmission. Devices 705 a-c, which include an interferingdevice 705 a, intended device 705 b, and impacted device 705 c, cancommunicate via a wireless channel. Interfering device 705 a andintended device 705 b are associated with BSS-A, while impacted device705 c is associated with BSS-B. In this example, impacted device 705 cmay detect interference, e.g., signals, from interfering device 705 aand decide to transmit a sounding request 730. In response to receivingthe sounding request 730, interfering device 705 a can transmit asounding announcement packet such as an NDP Announcement (NDP-A) 740 toindicate that a sounding packet such as an NDP will be transmitted. TheNDP-A 740 can include an indicator conveying that it is for aninterference avoidance sounding process. The NDP-A 740 can include adestination address field having a network address associated withimpacted device 705 c.

After transmission of the NDP-A 740, interfering device 705 a cantransmit the corresponding NDP 745. Impacted device 705 c can receivethe NDP-A 740 and the NDP 745, and based at least on the latter,determine information about a wireless channel between itself andinterfering device 705 a. Impacted device 705 c can generate a feedbackpacket 755 based on the wireless channel information and transmit thefeedback packet 755 to interfering device 705 a. In someimplementations, the feedback packet 755 can include CSI. In someimplementations, the feedback packet 755 can include a compressed or anon-compressed steering matrix. In some implementations, the feedbackpacket 755 can include compressed V matrix feedback, or a non-compressedV matrix feedback. In some implementations, the feedback packet 755 caninclude a compressed or a non-compressed null steering matrix.

Interfering device 705 a can use the feedback packet 755 to determine asteering matrix for an interference avoidance beamforming transmission760 to intended device 705 b that minimizes signal transmission towardsimpacted device 705 c. In some implementations, based on a successfulreception of the beamforming transmission 760, intended device 705 b cansend an ACK 765.

FIG. 8 shows an example of a wireless communication sequence thatincludes an explicit sounding sequence with multiple impacted devicesfor an interference avoidance beamforming transmission. Devices 805 a-d,which include interfering device 805 a, intended device 805 b, impacteddevice A 805 c, and impacted device B 805 d, can communicate via awireless channel. Interfering device 805 a and intended device 805 b areassociated with BSS-A, while impacted device A 805 c is associated withBSS-B and impacted device B 805 c is associated with BSS-C. In someimplementations, impacted device A 805 c may detect interference, e.g.,signals, from interfering device 805 a and decide to transmit a soundingrequest 830 to inform the interfering device 805 a about theinterference.

Interfering device 805 a can transmit an NDP-A 840 to indicate that anNDP 845 will be transmitted. The NDP-A 840 can include an indicator,such as one or more bits in a header field, conveying that it is for aninterference avoidance sounding process. Further, the NDP-A 840 caninclude a destination address field having a broadcast address. By usinga broadcast address, the interfering device 805 a can determine whetherthere are other impacted devices. In some implementations, the NDP-A 840is sent in response to receiving the sounding request 830. In someimplementations, the interfering device 805 a periodically sends theNDP-A 840 without receiving a sounding request 830 to proactivelyminimize interference to one or more devices.

After transmission of the NDP-A 840, interfering device 805 a cantransmit the corresponding NDP 845. Impacted devices 805 c-d can receivethe NDP-A 840 and the NDP 845, and based at least on the latter,determine information about wireless channels between themselves andinterfering device 805 a. Impacted devices 805 c-d can generate feedbackpackets 855 a-b based on the determined wireless channel information andtransmit the feedback packets 855 a-b to interfering device 805 a. Theimpacted devices 805 c-d can separately wait a randomized delay intervalbefore sending their respective feedback packets 855 a-b to minimize thechance of collision. In some implementations, the feedback packets 855a-b can include CSI such as one or more Signal to Noise Ratio (SNR)values for one or more transmission antennas being sounded by the NDP845. In some implementations, the feedback packets 855 a-b can include acompressed or on-compressed steering matrix. In some implementations,the feedback packets 855 a-b can include compressed V matrix feedback,or a non-compress V matrix feedback. In some implementations, thefeedback packets 855 a-b can include a compressed or a non-compressednull steering matrix.

Interfering device 805 a can use the feedback packets 855 a-b todetermine a steering matrix for an interference avoidance beamformingtransmission 860 to intended device 805 b that minimizes signaltransmission towards one or more of the impacted devices 805 c-d. Insome implementations, interfering device 805 a can select an impacteddevice from a group of impacted devices 805 c-d experiencing thestrongest interference, and compute a steering matrix for theinterference avoidance beamforming transmission 860 based on thefeedback packet from the selected impacted device. In someimplementations, the selection of the impacted device is determined bycomparing SNR values in channel feedback packets. In someimplementations, interfering device 805 a can compute a steering matrixfor the interference avoidance beamforming transmission 860 based on ajoint null space calculation, e.g., Q_(i)∈null(H_(L1), H_(L2), . . . ).

FIG. 9 shows an example of a wireless communication sequence thatincludes an implicit sounding sequence for an interference avoidancebeamforming transmission. Devices 905 a-c, which include an interferingdevice 905 a, intended device 905 b, and impacted device 905 c, cancommunicate via a wireless channel. Interfering device 905 a andintended device 905 b are associated with BSS-A, while impacted device905 c is associated with BSS-B. Interfering device 905 a performs anominal beamforming transmission 910 to the intended device 905 b. Insome implementations, based on a successful reception of the beamformingtransmission 910, intended device 905 b can send an ACK 915. In thisexample, impacted device 905 c may detect interference, e.g., signalsassociated with the nominal beamforming transmission 910, frominterfering device 905 a and decide to start an interference avoidancesounding process by sending an NDP-A 940 to indicate that an NDP 945will be transmitted. The NDP-A 940 can include an indicator conveyingthat it is for an interference avoidance sounding process. Further, theNDP-A 940 can include a destination address field having a broadcastaddress. After transmission of the NDP-A 940, impacted device 905 c cantransmit the corresponding NDP 945.

Interfering device 905 a can receive the NDP 945 and use it to determinea channel matrix H_(implicit) for a wireless channel between itself andinterfering device 905 a. The interfering device 905 a can compute atranspose of H_(implicit) to determine H_(L), V_(⊥H) _(L) , and Q_(i).Interfering device 905 a can use Q_(i) for an interference avoidancebeamforming transmission 960 to intended device 905 b that minimizessignal transmission towards Impacted device 905 c.

In some implementations, the interfering device 905 a can receivesounding packets from multiple impacted devices. In someimplementations, based on comparing interference information extractedfrom the sounding packets, the interfering device 905 a can select animpacted device that experiences the most interference from theinterfering device 905 a. In some implementations, the interferingdevice 905 a can compute a joint steering matrix based on null spaces ofleakage channel matrices indicated by two or more sounding packets fromtwo or more impacted devices.

In some implementations, a technique for interference avoidancebeamforming transmissions can include accessing, at a first device, datafor transmission to a second device; performing, at the first device, achannel sounding process with a third device to obtain channel feedbackregarding a wireless channel between the first device and the thirddevice; determining a steering matrix based on the channel feedback toreduce interference leakage received by the third device during abeamforming transmission from the first device to the second device; andperforming, at the first device, the beamforming transmission to thesecond device based on the data and the steering matrix. Otherimplementations are directed to systems, devices and computer-readable,storage mediums.

These and other implementations can include one or more of the followingfeatures. In some implementations, determining the steering matrix caninclude determining a null steering matrix responsive to the channelfeedback, the null steering matrix being based on a null space of awireless channel matrix associated with the wireless channel. In someimplementations, determining the steering matrix can include determininga first matrix responsive to the channel feedback, the first matrixbeing based on a null space of a wireless channel matrix associated withthe wireless channel; and determining a second matrix to improve aperformance of the beamforming transmission with respect to the seconddevice, the steering matrix being based on the first matrix and thesecond matrix. In some implementations, the channel sounding process caninclude transmitting a sounding announcement packet to the third device,the sounding announcement packet can include an interference avoidanceindicator; transmitting a sounding packet after transmitting thesounding announcement packet; and receiving the channel feedback fromthe third device, the channel feedback being based on the soundingpacket. In some implementations, the steering matrix is based on a nullspace of a wireless channel matrix that represents channel stateinformation, the channel state information being included in the channelfeedback. In some implementations, determining the steering matrix caninclude determining a null steering matrix based on steering matrixfeedback such that columns in the null steering matrix form basisvectors in a null-space of a wireless channel matrix associated with thethird device, the steering matrix feedback being included in the channelfeedback. In some implementations, the channel sounding process caninclude receiving, at the first device, a sounding announcement packetfrom the third device, the sounding announcement packet can include aninterference avoidance indicator; receiving, at the first device, asounding packet from the third device after receiving the soundingannouncement packet; and determining, at the first device, the channelfeedback based on the sounding packet. In some implementations, thesecond device and the third device are associated with different basicservice sets, the basic service sets overlapping in a frequency band.

An apparatus can include first circuitry configured to access data fortransmission to a first device; and second circuitry configured tocontrol a channel sounding process with a second device to obtainchannel feedback regarding a wireless channel between the apparatus andthe second device, determine a steering matrix based on the channelfeedback to reduce interference leakage received by the second deviceduring a beamforming transmission from the apparatus to the firstdevice, and control the beamforming transmission to the first devicebased on the data and the steering matrix. In some implementations, thesteering matrix is based on a null steering matrix. In someimplementations, the second circuitry is configured to determine thenull steering matrix responsive to the channel feedback, the nullsteering matrix being based on a null space of a wireless channel matrixassociated with the wireless channel. In some implementations, thesecond circuitry is configured to determine a first matrix responsive tothe channel feedback, the first matrix being based on a null space of awireless channel matrix associated with the wireless channel, anddetermine a second matrix to improve a performance of the beamformingtransmission with respect to the first device, the steering matrix beingbased on the first matrix and the second matrix. In someimplementations, the channel sounding process can include transmitting asounding announcement packet to the second device, the soundingannouncement packet can include an interference avoidance indicator;transmitting a sounding packet after transmitting the soundingannouncement packet; and receiving the channel feedback from the seconddevice, the channel feedback being based on the sounding packet. In someimplementations, wherein the steering matrix is based on a null space ofa wireless channel matrix that represents channel state information, thechannel state information being included in the channel feedback. Insome implementations, the second circuitry is configured to determinethe null steering matrix based on steering matrix feedback such thatcolumns in the null steering matrix form basis vectors in a null-spaceof a wireless channel matrix associated with the second device, thesteering matrix feedback being included in the channel feedback. In someimplementations, the channel sounding process can include receiving asounding announcement packet from the second device, the soundingannouncement packet can include an interference avoidance indicator;receiving a sounding packet from the second device after receiving thesounding announcement packet; and determining the channel feedback basedon the sounding packet. In some implementations, wherein the firstdevice and the second device are associated with different basic servicesets, the basic service sets overlapping in a frequency band.

A system can include transceiver electronics configured to wirelesslycommunicate with devices including a first device and a second device;and processor electronics coupled with the transceiver electronics. Theprocessor electronics can be configured to access data for transmissionto the first device, control a channel sounding process with the seconddevice to obtain channel feedback regarding a wireless channel betweenthe system and the second device, determine a steering matrix based onthe channel feedback to reduce interference leakage received by thesecond device during a beamforming transmission from the system to thefirst device, and control the beamforming transmission to the firstdevice based on the data and the steering matrix. In someimplementations, the steering matrix is based on a null steering matrix;and wherein the processor electronics are configured to determine thenull steering matrix responsive to the channel feedback, the nullsteering matrix being based on a null space of a wireless channel matrixassociated with the wireless channel. In some implementations, theprocessor electronics are configured to determine a first matrixresponsive to the channel feedback, the first matrix being based on anull space of a wireless channel matrix associated with the wirelesschannel, and determine a second matrix to improve a performance of thebeamforming transmission with respect to the first device, the steeringmatrix being based on the first matrix and the second matrix. In someimplementations, the channel sounding process can include transmitting asounding announcement packet to the second device, the soundingannouncement packet can include an interference avoidance indicator;transmitting a sounding packet after transmitting the soundingannouncement packet; and receiving the channel feedback from the seconddevice, the channel feedback being based on the sounding packet. In someimplementations, the steering matrix is based on a null space of awireless channel matrix that represents channel state information, thechannel state information being included in the channel feedback. Insome implementations, the processor electronics are configured todetermine the null steering matrix based on steering matrix feedback sthat columns in the null steering matrix form basis vectors in anull-space of a wireless channel matrix associated with the seconddevice, the steering matrix feedback being included in the channelfeedback. In some implementations, the channel sounding process caninclude receiving a sounding announcement packet from the second device,the sounding announcement packet can include an interference avoidanceindicator; receiving a sounding packet from the second device afterreceiving the sounding announcement packet; and determining the channelfeedback based on the sounding packet. In some implementations, thefirst device and the second device are associated with different basicservice sets, the basic service sets overlapping in a frequency band.

A few embodiments have been described in detail above, and variousmodifications are possible. The disclosed subject matter, including thefunctional operations described in this specification, cat beimplemented in electronic circuitry, computer hardware, firmware,software, or in combinations of them, such as the structural meansdisclosed in this specification and structural equivalents thereof,including potentially a program operable to cause one or more dataprocessing apparatus to perform the operations described (such as aprogram encoded in a computer-readable medium, which can be a memorydevice, a storage device, a machine-readable storage substrate, or otherphysical, machine-readable medium, or a combination of one or more ofthem).

The term “data processing apparatus” encompasses all apparatus, devices,and machines for processing data, including by way of example aprogrammable processor, a computer, or multiple processors or computers.The apparatus can include, in addition to hardware, code that creates anexecution environment for the computer program in question, e.g., codethat constitutes processor firmware, a protocol stack, a databasemanagement system, an operating system, or a combination of one or moreof them.

A program (also known as a computer program, software, softwareapplication, script, or code) can be written in any form of programinglanguage, including compiled or interpreted languages, or declarative orprocedural languages, and it can be deployed in any form, including as astand alone program or as a module, component, subroutine, or other unitsuitable for use in a computing environment. A program does notnecessarily correspond to a file in a file system. A program can bestored in a portion of a file that holds other programs or data (e.g.,one or more scripts stored in a markup language document), in a singlefile dedicated to the program in question, or in multiple coordinatedfiles (e.g., files that store one or more modules, sub programs, orportions of code). A program can be deployed to be executed on onecomputer or on multiple computers that are located at one site ordistributed across multiple sites and interconnected by a communicationnetwork.

While this specification contains many specifics, these should not beconstrued as limitations on the scope of what may be claimed, but ratheras descriptions of features that may be specific to particularembodiments. Certain features that are described in this specificationin the context of separate embodiments can also be implemented incombination in a single embodiment. Conversely, various features thatare described in the context of a single embodiment can also beimplemented in multiple embodiments separately or in any suitablesubcombination. Moreover, although features may be described above asacting in certain combinations and even initially claimed as such, oneor more features from a claimed combination can in some cases be excisedfrom the combination, and the claimed combination may be directed to asubcombination or variation of a subcombination.

Similarly, while operations are depicted in the drawings in a particularorder, this should not be understood as requiring that such operationsbe performed in the particular order shown or in sequential order, orthat all illustrated operations be performed, to achieve desirableresults. In certain circumstances, multitasking and parallel processingmay be advantageous. Moreover, the separation of various systemcomponents in the embodiments described above should not be understoodas requiring such separation in all embodiments.

Other embodiments fall within the scope of the following claims.

What is claimed is:
 1. A method comprising: accessing, at a firstdevice, data for a single-user beamforming transmission from the firstdevice to a second device; performing, at the first device, a channelsounding process with the second device to obtain channel feedbackregarding a wireless channel between the first device and the seconddevice; determining, responsive to the channel feedback, a first matrixto improve a performance of the single-user beamforming transmissionwith respect to the second device; receiving, at the first device, apacket from a third device; determining a channel estimation for awireless channel between the first device and the third device based onthe received packet; determining, responsive to the received packet, asecond matrix to reduce interference leakage received by the thirddevice during the single-user beamforming transmission from the firstdevice to the second device, the second matrix being based on atranspose of the channel estimation; and performing, at the firstdevice, the single-user beamforming transmission to the second devicebased on the data and a steering matrix, wherein the steering matrix isbased on the first matrix and the second matrix.
 2. The method of claim1, wherein the third device is configured to send the packet to causethe first device to reduce interference leakage received by the thirddevice during beamforming transmissions from the first device to thesecond device.
 3. The method of claim 1, wherein determining the secondmatrix comprises determining a null steering matrix based on a nullspace of the transpose of the channel estimation.
 4. The method of claim1, wherein the second device and the third device are associated withdifferent basic service sets, the basic service sets overlapping in afrequency band.
 5. The method of claim 1, wherein the received packetcomprises an interference avoidance indicator, and wherein the receivedpacket comprises a sounding packet.
 6. The method of claim 5, whereinthe received packet comprises a sounding announcement packet, andwherein the sounding announcement packet comprises the interferenceavoidance indicator.
 7. An apparatus comprising: a memory to store datafor a beamforming transmission to a first device; and processorelectronics coupled with the memory, wherein the processor electronicsare configured to: control a first channel sounding process with thefirst device to obtain first channel feedback regarding a wirelesschannel between the apparatus and the first device, determine,responsive to the first channel feedback, a first matrix to improve aperformance of the beamforming transmission with respect to the firstdevice, control a second channel sounding process with a second deviceto obtain second channel feedback regarding a wireless channel betweenthe apparatus and the second device, determine, responsive to the secondchannel feedback, a second matrix to reduce interference leakagereceived by the second device during the beamforming transmission, andcontrol the beamforming transmission to the first device based on thedata and a steering matrix, the steering matrix being based on the firstmatrix and the second matrix, wherein the second channel soundingprocess comprises (i) transmitting a sounding announcement packet to thesecond device, the sounding announcement packet comprising aninterference avoidance indicator, (ii) transmitting a sounding packetafter transmitting the sounding announcement packet, and (iii) receivingthe second channel feedback from the second device, the second channelfeedback being based on the sounding packet.
 8. The apparatus of claim7, wherein the second device initiates the second channel soundingprocess to reduce interference.
 9. The apparatus of claim 7, wherein thesecond matrix is based on a null steering matrix, and wherein theprocessor electronics are configured to determine the null steeringmatrix responsive to the second channel feedback, the null steeringmatrix being based on a null space of a wireless channel matrixassociated with the wireless channel between the apparatus and thesecond device.
 10. The apparatus of claim 7, wherein the second matrixis based on channel state information, the channel state informationbeing included in the second channel feedback.
 11. The apparatus ofclaim 7, wherein the second matrix is based on a null steering matrix,and wherein the processor electronics are configured to determine thenull steering matrix based on steering matrix feedback such that columnsin the null steering matrix form basis vectors in a null space of awireless channel matrix associated with the second device, the steeringmatrix feedback being included in the second channel feedback.
 12. Theapparatus of claim 7, wherein the first device and the second device areassociated with different basic service sets, the basic service setsoverlapping in a frequency band.
 13. A system comprising: transceiverelectronics configured to wirelessly communicate with devices includinga first device and a second device; and processor electronics coupledwith the transceiver electronics, wherein the processor electronics areconfigured to access data for a beamforming transmission to the firstdevice, control a first channel sounding process with the first deviceto obtain first channel feedback regarding a wireless channel betweenthe system and the first device, control a second channel soundingprocess with a second device to obtain second channel feedback regardinga wireless channel between the system and the second device, the secondchannel sounding process comprising transmitting a sounding announcementpacket to the second device, the sounding announcement packet comprisingan interference avoidance indicator, determine a steering matrix basedon the first channel feedback and the second channel feedback such thatinterference leakage received by the second device during thebeamforming transmission is reduced, and control the beamformingtransmission, via the transceiver electronics, to the first device basedon the data and the steering matrix, wherein the second channel soundingprocess comprises (i) transmitting a sounding packet after transmittingthe sounding announcement packet, and (ii) receiving the second channelfeedback from the second device, the second channel feedback being basedon the sounding packet.
 14. The system of claim 13, wherein theprocessor electronics are configured to: determine, responsive to thefirst channel feedback, a first matrix to improve a performance of thebeamforming transmission with respect to the first device, anddetermine, responsive to the second channel feedback, a second matrix toreduce interference leakage received by the second device during thebeamforming transmission, and wherein the steering matrix is based onthe first matrix and the second matrix.
 15. The system of claim 14,wherein the second matrix is based on a null steering matrix, andwherein the processor electronics are configured to determine the nullsteering matrix responsive to the second channel feedback, the nullsteering matrix being based on a null space of a wireless channel matrixassociated with the wireless channel between the system and the seconddevice.
 16. The system of claim 14, wherein the second matrix is basedon a null steering matrix, and wherein the processor electronics areconfigured to determine the null steering matrix based on steeringmatrix feedback such that columns in the null steering matrix form basisvectors in a null space of a wireless channel matrix associated with thesecond device, the steering matrix feedback being included in the secondchannel feedback.
 17. The system of claim 13, wherein the first deviceand the second device are associated with different basic service sets,the basic service sets overlapping in a frequency band.